Nanotechnology for Industrial Applications in Life Science

5 credits

Syllabus, Master's level, 1TE698

Education cycle
Second cycle
Main field(s) of study and in-depth level
Materials Engineering A1N, Technology A1N
Grading system
Pass with distinction, Pass with credit, Pass, Fail
Finalised by
The Faculty Board of Science and Technology, 7 February 2023
Responsible department
Department of Materials Science and Engineering

Entry requirements

120 credits in science/engineering/pharmacy. Proficiency in English equivalent to the Swedish upper secondary course English 6.

Learning outcomes

On completion of the course, the student should be able to:

  • discuss and analyse problems regarding definitions and terminology in the field of nanotechnology in different areas of life sciences as well as relate them to regulatory aspects,
  • apply and describe the most common bottom-up and top-down processes for the synthesis of nanomaterials and, with access to limited information, choose the appropriate process for a given application,
  • select the appropriate characterization method and independently use relevant characterization tools for a given application,
  • explain complex health and environmental risk factors associated with nanoparticles and how different risks can be evaluated,
  • provide examples of international and national industrial applications and development projects in which nanotechnology is used in the life sciences area, as well as scientifically explain why nanotechnology is an essential prerequisite for their implementation.


The aim of the course is to provide students with a basic understanding of how nanomaterials and nanotechnology can be used to develop new materials, products and methods for industrial applications in a wide field of life sciences as well as to give the students a foundation for working with synthesis, characterization , applications and safety related to nanomaterials and nanostructures in industrial nanotechnological development projects.

Introduction to Nanoscience and Nanotechnology. Synthesis of nanomaterials: bottom-up vs. top-down strategies. Characterization of nanomaterials: nanoparticle size and surface charge characterization, analysis of nanoporous materials, electron microscopy and atomic force microscope (AFM). Safety and risk factors associated with nanomaterials. Characterization of cell and blood toxicity of nanomaterials. Formulation strategies for nanomaterials intended as drug carriers. Diagnostics, teranostics (therapy methods combined with diagnostic tools), and imaging using nanotechnology. Nanomedicine and nanocosmetics for skin applications. Nanotechnology for gene delivery. Protein-based nanomaterials and nanostructures.


Lectures, guest lectures, seminars and laboratory exercises. The laboratory tasks as well as the laboratory groups are defined in such a way as to utilize prior knowledge and skills of the heterogeneous student group.


Active participation in all seminars and an oral examination in the form of an open seminar in smaller groups (4 credits). Written reports from laboration (1 credit).